Context Navigation

source: git/kernel/longrat.cc @ 8fd3bd5

spielwiese

Last change on this file since 8fd3bd5 was 8fd3bd5, checked in by Hans Schoenemann <hannes@…>, 13 years ago
nlDTest fixes some errors git-svn-id: file:///usr/local/Singular/svn/trunk@13920 2c84dea3-7e68-4137-9b89-c4e89433aadc
Property mode set to `100644`
File size: 48.5 KB

Line
1	/****************************************
2	* Computer Algebra System SINGULAR *
3	****************************************/
4	/* $Id$ */
5	/*
6	* ABSTRACT: computation with long rational numbers (Hubert Grassmann)
7	*/
8
9	#include <kernel/mod2.h>
10	#include <kernel/structs.h>
11	#include <kernel/longrat.h>
12
13	// 64 bit version:
14	#if 0
15	#define MAX_NUM_SIZE 60
16	#define POW_2_28 0x10000000000000L
17	#define LONG long
18	#else
19	#define MAX_NUM_SIZE 28
20	#define POW_2_28 (1L<<28)
21	#define LONG int
22	#endif
23
24	static inline number nlShort3(number x) // assume x->s==3
25	{
26	assume(x->s==3);
27	if ((mpz_cmp_ui(x->z,(long)0)==0)
28	\|\| (mpz_size1(x->z)<=MP_SMALL))
29	{
30	LONG ui=mpz_get_si(x->z);
31	if ((((ui<<3)>>3)==ui)
32	&& (mpz_cmp_si(x->z,(long)ui)==0))
33	{
34	mpz_clear(x->z);
35	omFreeBin((ADDRESS)x, rnumber_bin);
36	return INT_TO_SR(ui);
37	}
38	}
39	return x;
40	}
41
42	#ifndef LONGRAT_CC
43	#define LONGRAT_CC
44
45	#include <string.h>
46	#include <float.h>
47	#include <omalloc/omalloc.h>
48	#include <kernel/febase.h>
49	#include <kernel/numbers.h>
50	#include <kernel/modulop.h>
51	#include <kernel/ring.h>
52	#include <kernel/shortfl.h>
53	#include <kernel/mpr_complex.h>
54
55
56	#ifndef BYTES_PER_MP_LIMB
57	#define BYTES_PER_MP_LIMB sizeof(mp_limb_t)
58	#endif
59
60	/-----------------------------------------------------------------/
61	/*3
62	* parameter s in number:
63	* 0 (or FALSE): not normalised rational
64	* 1 (or TRUE): normalised rational
65	* 3 : integer with n==NULL
66	*/
67	/*3
68	** 'SR_INT' is the type of those integers small enough to fit into 29 bits.
69	** Therefor the value range of this small integers is: $-2^{28}...2^{28}-1$.
70	**
71	** Small integers are represented by an immediate integer handle, containing
72	** the value instead of pointing to it, which has the following form:
73	**
74	** +-------+-------+-------+-------+- - - -+-------+-------+-------+
75	** \| guard \| sign \| bit \| bit \| \| bit \| tag \| tag \|
76	** \| bit \| bit \| 27 \| 26 \| \| 0 \| 0 \| 1 \|
77	** +-------+-------+-------+-------+- - - -+-------+-------+-------+
78	**
79	** Immediate integers handles carry the tag 'SR_INT', i.e. the last bit is 1.
80	** This distuingishes immediate integers from other handles which point to
81	** structures aligned on 4 byte boundaries and therefor have last bit zero.
82	** (The second bit is reserved as tag to allow extensions of this scheme.)
83	** Using immediates as pointers and dereferencing them gives address errors.
84	**
85	** To aid overflow check the most significant two bits must always be equal,
86	** that is to say that the sign bit of immediate integers has a guard bit.
87	**
88	** The macros 'INT_TO_SR' and 'SR_TO_INT' should be used to convert between
89	** a small integer value and its representation as immediate integer handle.
90	**
91	** Large integers and rationals are represented by z and n
92	** where n may be undefined (if s==3)
93	** NULL represents only deleted values
94	*/
95	#define SR_HDL(A) ((long)(A))
96	/#define SR_INT 1L/
97	/#define INT_TO_SR(INT) ((number) (((long)INT << 2) + SR_INT))/
98	// #define SR_TO_INT(SR) (((long)SR) >> 2)
99
100	#define MP_SMALL 1
101	//#define mpz_isNeg(A) (mpz_cmp_si(A,(long)0)<0)
102	#define mpz_isNeg(A) ((A)->_mp_size<0)
103	#define mpz_limb_size(A) ((A)->_mp_size)
104	#define mpz_limb_d(A) ((A)->_mp_d)
105	#define MPZ_DIV(A,B,C) mpz_tdiv_q((A),(B),(C))
106	#define MPZ_EXACTDIV(A,B,C) mpz_divexact((A),(B),(C))
107
108	void _nlDelete_NoImm(number *a);
109
110	/***************************************************************
111	*
112	* Routines which are never inlined by p_Numbers.h
113	*
114	*******************************************************************/
115	#ifndef P_NUMBERS_H
116
117	number nlShort3_noinline(number x) // assume x->s==3
118	{
119	return nlShort3(x);
120	}
121
122	omBin rnumber_bin = omGetSpecBin(sizeof(snumber));
123
124	number nlOne=INT_TO_SR(1);
125
126	#if (__GNU_MP_VERSION*10+__GNU_MP_VERSION_MINOR < 31)
127	void mpz_mul_si (mpz_ptr r, mpz_srcptr s, long int si)
128	{
129	if (si>=0)
130	mpz_mul_ui(r,s,si);
131	else
132	{
133	mpz_mul_ui(r,s,-si);
134	mpz_neg(r,r);
135	}
136	}
137	#endif
138
139	static ring nlMapRing;
140	static number nlMapP(number from)
141	{
142	number to;
143	to = nlInit(npInt(from,nlMapRing), currRing);
144	return to;
145	}
146
147	static number nlMapLongR(number from);
148	static number nlMapR(number from);
149
150	#ifdef HAVE_RINGS
151	/*2
152	* convert from a GMP integer
153	*/
154	number nlMapGMP(number from)
155	{
156	number z=(number)omAllocBin(rnumber_bin);
157	#if defined(LDEBUG)
158	z->debug=123456;
159	#endif
160	mpz_init_set(z->z,(mpz_ptr) from);
161	//mpz_init_set_ui(&z->n,1);
162	z->s = 3;
163	z=nlShort3(z);
164	return z;
165	}
166
167	/*2
168	* convert from an machine long
169	*/
170	number nlMapMachineInt(number from)
171	{
172	number z=(number)omAllocBin(rnumber_bin);
173	#if defined(LDEBUG)
174	z->debug=123456;
175	#endif
176	mpz_init_set_ui(z->z,(unsigned long) from);
177	z->s = 3;
178	z=nlShort3(z);
179	return z;
180	}
181	#endif
182
183	nMapFunc nlSetMap(const ring src, const ring dst)
184	{
185	if (rField_is_Q(src))
186	{
187	return nlCopy;
188	}
189	nlMapRing=src;
190	if (rField_is_Zp(src))
191	{
192	return nlMapP;
193	}
194	if (rField_is_R(src))
195	{
196	return nlMapR;
197	}
198	if (rField_is_long_R(src))
199	{
200	return nlMapLongR; /* long R -> Q */
201	}
202	#ifdef HAVE_RINGS
203	if (rField_is_Ring_Z(src) \|\| rField_is_Ring_PtoM(src) \|\| rField_is_Ring_ModN(src))
204	{
205	return nlMapGMP;
206	}
207	if (rField_is_Ring_2toM(src))
208	{
209	return nlMapMachineInt;
210	}
211	#endif
212	return NULL;
213	}
214
215	#ifdef LDEBUG
216	BOOLEAN nlDBTest(number a, const char *f,const int l)
217	{
218	if (a==NULL)
219	{
220	Print("!!longrat: NULL in %s:%d\n",f,l);
221	return FALSE;
222	}
223	//if ((int)a==1) Print("!! 0x1 as number ? %s %d\n",f,l);
224	if ((((long)a)&3L)==3L)
225	{
226	Print(" !!longrat:ptr(3) in %s:%d\n",f,l);
227	return FALSE;
228	}
229	if ((((long)a)&3L)==1L)
230	{
231	if (((((LONG)(long)a)<<1)>>1)!=((LONG)(long)a))
232	{
233	Print(" !!longrat:arith:%lx in %s:%d\n",(long)a, f,l);
234	return FALSE;
235	}
236	return TRUE;
237	}
238	omCheckIf(omCheckAddrSize(a,sizeof(*a)), return FALSE);
239	if (a->debug!=123456)
240	{
241	Print("!!longrat:debug:%d in %s:%d\n",a->debug,f,l);
242	a->debug=123456;
243	return FALSE;
244	}
245	if ((a->s<0)\|\|(a->s>4))
246	{
247	Print("!!longrat:s=%d in %s:%d\n",a->s,f,l);
248	return FALSE;
249	}
250	omCheckAddrSize(a->z[0]._mp_d,a->z[0]._mp_alloc*BYTES_PER_MP_LIMB);
251	if (a->z[0]._mp_alloc==0)
252	Print("!!longrat:z->alloc=0 in %s:%d\n",f,l);
253
254	if (a->s<2)
255	{
256	omCheckIf(omCheckAddrSize(a->n[0]._mp_d,a->n[0]._mp_alloc*BYTES_PER_MP_LIMB), return FALSE);
257	if (a->z[0]._mp_alloc==0)
258	Print("!!longrat:n->alloc=0 in %s:%d\n",f,l);
259	if ((mpz_size1(a->n) ==1) && (mpz_cmp_si(a->n,(long)1)==0))
260	{
261	Print("!!longrat:integer as rational in %s:%d\n",f,l);
262	mpz_clear(a->n); a->s=3;
263	return FALSE;
264	}
265	else if (mpz_isNeg(a->n))
266	{
267	Print("!!longrat:div. by negative in %s:%d\n",f,l);
268	mpz_neg(a->z,a->z);
269	mpz_neg(a->n,a->n);
270	return FALSE;
271	}
272	return TRUE;
273	}
274	//if (a->s==2)
275	//{
276	// Print("!!longrat:s=2 in %s:%d\n",f,l);
277	// return FALSE;
278	//}
279	if (mpz_size1(a->z)>MP_SMALL) return TRUE;
280	LONG ui=(int)mpz_get_si(a->z);
281	if ((((ui<<3)>>3)==ui)
282	&& (mpz_cmp_si(a->z,(long)ui)==0))
283	{
284	Print("!!longrat:im int %d in %s:%d\n",ui,f,l);
285	f=NULL;
286	return FALSE;
287	}
288	return TRUE;
289	}
290	#endif
291
292	number nlRInit (long i);
293
294	static number nlMapR(number from)
295	{
296	double f=nrFloat(from);
297	if (f==0.0) return INT_TO_SR(0);
298	int f_sign=1;
299	if (f<0.0)
300	{
301	f_sign=-1;
302	f=-f;
303	}
304	int i=0;
305	mpz_t h1;
306	mpz_init_set_ui(h1,1);
307	while((FLT_RADIX*f) < DBL_MAX && i<DBL_MANT_DIG)
308	{
309	f*=FLT_RADIX;
310	mpz_mul_ui(h1,h1,FLT_RADIX);
311	i++;
312	}
313	number r=nlRInit(1);
314	mpz_set_d(r->z,f);
315	memcpy4(&(r->n),&h1,sizeof(h1));
316	r->s=0; /* not normalized */
317	if(f_sign==-1) r=nlNeg(r);
318	nlNormalize(r);
319	return r;
320	}
321
322	static number nlMapLongR(number from)
323	{
324	gmp_float ff=(gmp_float)from;
325	mpf_t *f=ff->_mpfp();
326	number res;
327	mpz_ptr dest,ndest;
328	int size, i,negative;
329	int e,al,bl;
330	mp_ptr qp,dd,nn;
331
332	size = (*f)[0]._mp_size;
333	if (size == 0)
334	return INT_TO_SR(0);
335	if(size<0)
336	{
337	negative = 1;
338	size = -size;
339	}
340	else
341	negative = 0;
342
343	qp = (*f)[0]._mp_d;
344	while(qp[0]==0)
345	{
346	qp++;
347	size--;
348	}
349
350	e=(*f)[0]._mp_exp-size;
351	res = (number)omAllocBin(rnumber_bin);
352	#if defined(LDEBUG)
353	res->debug=123456;
354	#endif
355	dest = res->z;
356
357	if (e<0)
358	{
359	al = dest->_mp_size = size;
360	if (al<2) al = 2;
361	dd = (mp_ptr)omAlloc(sizeof(mp_limb_t)*al);
362	for (i=0;i<size;i++) dd[i] = qp[i];
363	bl = 1-e;
364	nn = (mp_ptr)omAlloc(sizeof(mp_limb_t)*bl);
365	nn[bl-1] = 1;
366	for (i=bl-2;i>=0;i--) nn[i] = 0;
367	ndest = res->n;
368	ndest->_mp_d = nn;
369	ndest->_mp_alloc = ndest->_mp_size = bl;
370	res->s = 0;
371	}
372	else
373	{
374	al = dest->_mp_size = size+e;
375	if (al<2) al = 2;
376	dd = (mp_ptr)omAlloc(sizeof(mp_limb_t)*al);
377	for (i=0;i<size;i++) dd[i+e] = qp[i];
378	for (i=0;i<e;i++) dd[i] = 0;
379	res->s = 3;
380	}
381
382	dest->_mp_d = dd;
383	dest->_mp_alloc = al;
384	if (negative) dest->_mp_size = -dest->_mp_size;
385
386	if (res->s==0)
387	nlNormalize(res);
388	else
389	{
390	// res is new, res->ref is 1
391	res=nlShort3(res);
392	}
393	nlTest(res);
394	return res;
395	}
396
397	//static number nlMapLongR(number from)
398	//{
399	// gmp_float ff=(gmp_float)from;
400	// const mpf_t *f=ff->mpfp();
401	// int f_size=ABS((*f)[0]._mp_size);
402	// if (f_size==0)
403	// return nlInit(0);
404	// int f_sign=1;
405	// number work=ngcCopy(from);
406	// if (!ngcGreaterZero(work))
407	// {
408	// f_sign=-1;
409	// work=ngcNeg(work);
410	// }
411	// int i=0;
412	// mpz_t h1;
413	// mpz_init_set_ui(h1,1);
414	// while((FLT_RADIX*f) < DBL_MAX && i<DBL_MANT_DIG)
415	// {
416	// f*=FLT_RADIX;
417	// mpz_mul_ui(h1,h1,FLT_RADIX);
418	// i++;
419	// }
420	// number r=nlRInit(1);
421	// mpz_set_d(&(r->z),f);
422	// memcpy4(&(r->n),&h1,sizeof(h1));
423	// r->s=0; /* not normalized */
424	// nlNormalize(r);
425	// return r;
426	//
427	//
428	// number r=nlRInit(1);
429	// int f_shift=f_size+(*f)[0]._mp_exp;
430	// if ( f_shift > 0)
431	// {
432	// r->s=0;
433	// mpz_init(&r->n);
434	// mpz_setbit(&r->n,f_shiftBYTES_PER_MP_LIMB8);
435	// mpz_setbit(&r->z,f_sizeBYTES_PER_MP_LIMB8-1);
436	// // now r->z has enough space
437	// memcpy4(mpz_limb_d(&r->z),((f)[0]._mp_d),f_sizeBYTES_PER_MP_LIMB);
438	// nlNormalize(r);
439	// }
440	// else
441	// {
442	// r->s=3;
443	// if (f_shift==0)
444	// {
445	// mpz_setbit(&r->z,f_sizeBYTES_PER_MP_LIMB8-1);
446	// // now r->z has enough space
447	// memcpy4(mpz_limb_d(&r->z),((f)[0]._mp_d),f_sizeBYTES_PER_MP_LIMB);
448	// }
449	// else /* f_shift < 0 */
450	// {
451	// mpz_setbit(&r->z,(f_size-f_shift)BYTES_PER_MP_LIMB8-1);
452	// // now r->z has enough space
453	// memcpy4(mpz_limb_d(&r->z)-f_shift,((*f)[0]._mp_d),
454	// f_size*BYTES_PER_MP_LIMB);
455	// }
456	// }
457	// if ((*f)[0]._mp_size<0);
458	// r=nlNeg(r);
459	// return r;
460	//}
461
462	int nlSize(number a)
463	{
464	if (a==INT_TO_SR(0))
465	return 0; /* rational 0*/
466	if (SR_HDL(a) & SR_INT)
467	return 1; /* immidiate int */
468	int s=a->z[0]._mp_alloc;
469	// while ((s>0) &&(a->z._mp_d[s]==0L)) s--;
470	//#if SIZEOF_LONG == 8
471	// if (a->z._mp_d[s] < (unsigned long)0x100000000L) s=s*2-1;
472	// else s *=2;
473	//#endif
474	// s++;
475	if (a->s<2)
476	{
477	int d=a->n[0]._mp_alloc;
478	// while ((d>0) && (a->n._mp_d[d]==0L)) d--;
479	//#if SIZEOF_LONG == 8
480	// if (a->n._mp_d[d] < (unsigned long)0x100000000L) d=d*2-1;
481	// else d *=2;
482	//#endif
483	s+=d;
484	}
485	return s;
486	}
487
488	/*2
489	* convert number to int
490	*/
491	int nlInt(number &i, const ring r)
492	{
493	nlTest(i);
494	nlNormalize(i);
495	if (SR_HDL(i) &SR_INT) return SR_TO_INT(i);
496	if (i->s==3)
497	{
498	if(mpz_size1(i->z)>MP_SMALL) return 0;
499	int ul=(int)mpz_get_si(i->z);
500	if (mpz_cmp_si(i->z,(long)ul)!=0) return 0;
501	return ul;
502	}
503	mpz_t tmp;
504	int ul;
505	mpz_init(tmp);
506	MPZ_DIV(tmp,i->z,i->n);
507	if(mpz_size1(tmp)>MP_SMALL) ul=0;
508	else
509	{
510	ul=(int)mpz_get_si(tmp);
511	if (mpz_cmp_si(tmp,(long)ul)!=0) ul=0;
512	}
513	mpz_clear(tmp);
514	return ul;
515	}
516
517	/*2
518	* convert number to bigint
519	*/
520	number nlBigInt(number &i)
521	{
522	nlTest(i);
523	nlNormalize(i);
524	if (SR_HDL(i) &SR_INT) return (i);
525	if (i->s==3)
526	{
527	return nlCopy(i);
528	}
529	number tmp=nlRInit(1);
530	MPZ_DIV(tmp->z,i->z,i->n);
531	tmp=nlShort3(tmp);
532	return tmp;
533	}
534
535	/*
536	* 1/a
537	*/
538	number nlInvers(number a)
539	{
540	nlTest(a);
541	number n;
542	if (SR_HDL(a) & SR_INT)
543	{
544	if ((a==INT_TO_SR(1L)) \|\| (a==INT_TO_SR(-1L)))
545	{
546	return a;
547	}
548	if (nlIsZero(a))
549	{
550	WerrorS(nDivBy0);
551	return INT_TO_SR(0);
552	}
553	n=(number)omAllocBin(rnumber_bin);
554	#if defined(LDEBUG)
555	n->debug=123456;
556	#endif
557	n->s=1;
558	if ((long)a>0L)
559	{
560	mpz_init_set_si(n->z,(long)1);
561	mpz_init_set_si(n->n,(long)SR_TO_INT(a));
562	}
563	else
564	{
565	mpz_init_set_si(n->z,(long)-1);
566	mpz_init_set_si(n->n,(long)-SR_TO_INT(a));
567	}
568	nlTest(n);
569	return n;
570	}
571	n=(number)omAllocBin(rnumber_bin);
572	#if defined(LDEBUG)
573	n->debug=123456;
574	#endif
575	{
576	n->s=a->s;
577	mpz_init_set(n->n,a->z);
578	switch (a->s)
579	{
580	case 0:
581	case 1:
582	mpz_init_set(n->z,a->n);
583	if (mpz_isNeg(n->n)) /* && n->s<2*/
584	{
585	mpz_neg(n->z,n->z);
586	mpz_neg(n->n,n->n);
587	}
588	if (mpz_cmp_si(n->n,(long)1)==0)
589	{
590	mpz_clear(n->n);
591	n->s=3;
592	n=nlShort3(n);
593	}
594	break;
595	case 3:
596	n->s=1;
597	if (mpz_isNeg(n->n)) /* && n->s<2*/
598	{
599	mpz_neg(n->n,n->n);
600	mpz_init_set_si(n->z,(long)-1);
601	}
602	else
603	{
604	mpz_init_set_si(n->z,(long)1);
605	}
606	break;
607	}
608	}
609	nlTest(n);
610	return n;
611	}
612
613
614	/*2
615	* u := a / b in Z, if b \| a (else undefined)
616	*/
617	number nlExactDiv(number a, number b)
618	{
619	if (b==INT_TO_SR(0))
620	{
621	WerrorS(nDivBy0);
622	return INT_TO_SR(0);
623	}
624	if (a==INT_TO_SR(0))
625	return INT_TO_SR(0);
626	number u;
627	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
628	{
629	/* the small int -(1<<28) divided by -1 is the large int (1<<28) */
630	if ((a==INT_TO_SR(-(POW_2_28)))&&(b==INT_TO_SR(-1L)))
631	{
632	return nlRInit(POW_2_28);
633	}
634	long aa=SR_TO_INT(a);
635	long bb=SR_TO_INT(b);
636	return INT_TO_SR(aa/bb);
637	}
638	number bb=NULL;
639	if (SR_HDL(b) & SR_INT)
640	{
641	bb=nlRInit(SR_TO_INT(b));
642	b=bb;
643	}
644	u=(number)omAllocBin(rnumber_bin);
645	#if defined(LDEBUG)
646	u->debug=123456;
647	#endif
648	mpz_init(u->z);
649	/* u=a/b */
650	u->s = 3;
651	MPZ_EXACTDIV(u->z,a->z,b->z);
652	if (bb!=NULL)
653	{
654	mpz_clear(bb->z);
655	#if defined(LDEBUG)
656	bb->debug=654324;
657	#endif
658	omFreeBin((ADDRESS)bb, rnumber_bin);
659	}
660	u=nlShort3(u);
661	nlTest(u);
662	return u;
663	}
664
665	/*2
666	* u := a / b in Z
667	*/
668	number nlIntDiv (number a, number b)
669	{
670	if (b==INT_TO_SR(0))
671	{
672	WerrorS(nDivBy0);
673	return INT_TO_SR(0);
674	}
675	if (a==INT_TO_SR(0))
676	return INT_TO_SR(0);
677	number u;
678	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
679	{
680	/* the small int -(1<<28) divided by -1 is the large int (1<<28) */
681	if ((a==INT_TO_SR(-(POW_2_28)))&&(b==INT_TO_SR(-1L)))
682	{
683	return nlRInit(POW_2_28);
684	}
685	long aa=SR_TO_INT(a);
686	long bb=SR_TO_INT(b);
687	return INT_TO_SR(aa/bb);
688	}
689	if (SR_HDL(a) & SR_INT)
690	{
691	/* the small int -(1<<28) divided by 2^28 is 1 */
692	if (a==INT_TO_SR(-(POW_2_28)))
693	{
694	if(mpz_cmp_si(b->z,(POW_2_28))==0)
695	{
696	return INT_TO_SR(-1);
697	}
698	}
699	/* a is a small and b is a large int: -> 0 */
700	return INT_TO_SR(0);
701	}
702	number bb=NULL;
703	if (SR_HDL(b) & SR_INT)
704	{
705	bb=nlRInit(SR_TO_INT(b));
706	b=bb;
707	}
708	u=(number)omAllocBin(rnumber_bin);
709	#if defined(LDEBUG)
710	u->debug=123456;
711	#endif
712	assume(a->s==3);
713	assume(b->s==3);
714	mpz_init_set(u->z,a->z);
715	/* u=u/b */
716	u->s = 3;
717	MPZ_DIV(u->z,u->z,b->z);
718	if (bb!=NULL)
719	{
720	mpz_clear(bb->z);
721	#if defined(LDEBUG)
722	bb->debug=654324;
723	#endif
724	omFreeBin((ADDRESS)bb, rnumber_bin);
725	}
726	u=nlShort3(u);
727	nlTest(u);
728	return u;
729	}
730
731	/*2
732	* u := a mod b in Z, u>=0
733	*/
734	number nlIntMod (number a, number b)
735	{
736	if (b==INT_TO_SR(0))
737	{
738	WerrorS(nDivBy0);
739	return INT_TO_SR(0);
740	}
741	if (a==INT_TO_SR(0))
742	return INT_TO_SR(0);
743	number u;
744	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
745	{
746	if ((long)a>0L)
747	{
748	if ((long)b>0L)
749	return INT_TO_SR(SR_TO_INT(a)%SR_TO_INT(b));
750	else
751	return INT_TO_SR(SR_TO_INT(a)%(-SR_TO_INT(b)));
752	}
753	else
754	{
755	if ((long)b>0L)
756	{
757	long i=(-SR_TO_INT(a))%SR_TO_INT(b);
758	if ( i != 0L ) i = (SR_TO_INT(b))-i;
759	return INT_TO_SR(i);
760	}
761	else
762	{
763	long i=(-SR_TO_INT(a))%(-SR_TO_INT(b));
764	if ( i != 0L ) i = (-SR_TO_INT(b))-i;
765	return INT_TO_SR(i);
766	}
767	}
768	}
769	if (SR_HDL(a) & SR_INT)
770	{
771	/* a is a small and b is a large int: -> a or (a+b) or (a-b) */
772	if ((long)a<0L)
773	{
774	if (mpz_isNeg(b->z))
775	return nlSub(a,b);
776	/else/
777	return nlAdd(a,b);
778	}
779	/else/
780	return a;
781	}
782	number bb=NULL;
783	if (SR_HDL(b) & SR_INT)
784	{
785	bb=nlRInit(SR_TO_INT(b));
786	b=bb;
787	}
788	u=(number)omAllocBin(rnumber_bin);
789	#if defined(LDEBUG)
790	u->debug=123456;
791	#endif
792	mpz_init(u->z);
793	u->s = 3;
794	mpz_mod(u->z,a->z,b->z);
795	if (bb!=NULL)
796	{
797	mpz_clear(bb->z);
798	#if defined(LDEBUG)
799	bb->debug=654324;
800	#endif
801	omFreeBin((ADDRESS)bb, rnumber_bin);
802	}
803	if (mpz_isNeg(u->z))
804	{
805	if (mpz_isNeg(b->z))
806	mpz_sub(u->z,u->z,b->z);
807	else
808	mpz_add(u->z,u->z,b->z);
809	}
810	u=nlShort3(u);
811	nlTest(u);
812	return u;
813	}
814
815	/*2
816	* u := a / b
817	*/
818	number nlDiv (number a, number b)
819	{
820	number u;
821	if (nlIsZero(b))
822	{
823	WerrorS(nDivBy0);
824	return INT_TO_SR(0);
825	}
826	u=(number)omAllocBin(rnumber_bin);
827	u->s=0;
828	#if defined(LDEBUG)
829	u->debug=123456;
830	#endif
831	// ---------- short / short ------------------------------------
832	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
833	{
834	long i=SR_TO_INT(a);
835	long j=SR_TO_INT(b);
836	long r=i%j;
837	if (r==0)
838	{
839	omFreeBin((ADDRESS)u, rnumber_bin);
840	return INT_TO_SR(i/j);
841	}
842	mpz_init_set_si(u->z,(long)i);
843	mpz_init_set_si(u->n,(long)j);
844	}
845	else
846	{
847	mpz_init(u->z);
848	// ---------- short / long ------------------------------------
849	if (SR_HDL(a) & SR_INT)
850	{
851	// short a / (z/n) -> (a*n)/z
852	if (b->s<2)
853	{
854	mpz_mul_si(u->z,b->n,SR_TO_INT(a));
855	}
856	else
857	// short a / long z -> a/z
858	{
859	mpz_set_si(u->z,SR_TO_INT(a));
860	}
861	if (mpz_cmp(u->z,b->z)==0)
862	{
863	mpz_clear(u->z);
864	omFreeBin((ADDRESS)u, rnumber_bin);
865	return INT_TO_SR(1);
866	}
867	mpz_init_set(u->n,b->z);
868	}
869	// ---------- long / short ------------------------------------
870	else if (SR_HDL(b) & SR_INT)
871	{
872	mpz_set(u->z,a->z);
873	// (z/n) / b -> z/(n*b)
874	if (a->s<2)
875	{
876	mpz_init_set(u->n,a->n);
877	if ((long)b>0L)
878	mpz_mul_ui(u->n,u->n,SR_TO_INT(b));
879	else
880	{
881	mpz_mul_ui(u->n,u->n,-SR_TO_INT(b));
882	mpz_neg(u->z,u->z);
883	}
884	}
885	else
886	// long z / short b -> z/b
887	{
888	//mpz_set(u->z,a->z);
889	mpz_init_set_si(u->n,SR_TO_INT(b));
890	}
891	}
892	// ---------- long / long ------------------------------------
893	else
894	{
895	mpz_set(u->z,a->z);
896	mpz_init_set(u->n,b->z);
897	if (a->s<2) mpz_mul(u->n,u->n,a->n);
898	if (b->s<2) mpz_mul(u->z,u->z,b->n);
899	}
900	}
901	if (mpz_isNeg(u->n))
902	{
903	mpz_neg(u->z,u->z);
904	mpz_neg(u->n,u->n);
905	}
906	if (mpz_cmp_si(u->n,(long)1)==0)
907	{
908	mpz_clear(u->n);
909	u->s=3;
910	u=nlShort3(u);
911	}
912	nlTest(u);
913	return u;
914	}
915
916	/*2
917	* u:= x ^ exp
918	*/
919	void nlPower (number x,int exp,number * u)
920	{
921	*u = INT_TO_SR(0); // 0^e, e!=0
922	if (!nlIsZero(x))
923	{
924	nlTest(x);
925	number aa=NULL;
926	if (SR_HDL(x) & SR_INT)
927	{
928	aa=nlRInit(SR_TO_INT(x));
929	x=aa;
930	}
931	else if (x->s==0)
932	nlNormalize(x);
933	*u=(number)omAllocBin(rnumber_bin);
934	#if defined(LDEBUG)
935	(*u)->debug=123456;
936	#endif
937	mpz_init((*u)->z);
938	mpz_pow_ui((*u)->z,x->z,(unsigned long)exp);
939	if (x->s<2)
940	{
941	if (mpz_cmp_si(x->n,(long)1)==0)
942	{
943	x->s=3;
944	mpz_clear(x->n);
945	}
946	else
947	{
948	mpz_init((*u)->n);
949	mpz_pow_ui((*u)->n,x->n,(unsigned long)exp);
950	}
951	}
952	(*u)->s = x->s;
953	if ((u)->s==3) u=nlShort3(*u);
954	if (aa!=NULL)
955	{
956	mpz_clear(aa->z);
957	omFreeBin((ADDRESS)aa, rnumber_bin);
958	}
959	}
960	else if (exp==0)
961	*u = INT_TO_SR(1); // 0^0
962	#ifdef LDEBUG
963	if (exp<0) Print("nlPower: neg. exp. %d\n",exp);
964	nlTest(*u);
965	#endif
966	}
967
968
969	/*2
970	* za >= 0 ?
971	*/
972	BOOLEAN nlGreaterZero (number a)
973	{
974	nlTest(a);
975	if (SR_HDL(a) & SR_INT) return SR_HDL(a)>1L /* represents number(0) */;
976	return (!mpz_isNeg(a->z));
977	}
978
979	/*2
980	* a > b ?
981	*/
982	BOOLEAN nlGreater (number a, number b)
983	{
984	nlTest(a);
985	nlTest(b);
986	number r;
987	BOOLEAN rr;
988	r=nlSub(a,b);
989	rr=(!nlIsZero(r)) && (nlGreaterZero(r));
990	nlDelete(&r,currRing);
991	return rr;
992	}
993
994	/*2
995	* a == -1 ?
996	*/
997	BOOLEAN nlIsMOne (number a)
998	{
999	#ifdef LDEBUG
1000	if (a==NULL) return FALSE;
1001	nlTest(a);
1002	#endif
1003	//if (SR_HDL(a) & SR_INT) return (a==INT_TO_SR(-1L));
1004	//return FALSE;
1005	return (a==INT_TO_SR(-1L));
1006	}
1007
1008	/*2
1009	* result =gcd(a,b)
1010	*/
1011	number nlGcd(number a, number b, const ring r)
1012	{
1013	number result;
1014	nlTest(a);
1015	nlTest(b);
1016	//nlNormalize(a);
1017	//nlNormalize(b);
1018	if ((a==INT_TO_SR(1L))\|\|(a==INT_TO_SR(-1L))
1019	\|\| (b==INT_TO_SR(1L))\|\|(b==INT_TO_SR(-1L)))
1020	return INT_TO_SR(1L);
1021	if (a==INT_TO_SR(0)) /* gcd(0,b) ->b */
1022	return nlCopy(b);
1023	if (b==INT_TO_SR(0)) /* gcd(a,0) -> a */
1024	return nlCopy(a);
1025	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
1026	{
1027	long i=SR_TO_INT(a);
1028	long j=SR_TO_INT(b);
1029	if((i==0L)\|\|(j==0L))
1030	return INT_TO_SR(1);
1031	long l;
1032	i=ABS(i);
1033	j=ABS(j);
1034	do
1035	{
1036	l=i%j;
1037	i=j;
1038	j=l;
1039	} while (l!=0L);
1040	return INT_TO_SR(i);
1041	}
1042	if (((!(SR_HDL(a) & SR_INT))&&(a->s<2))
1043	\|\| ((!(SR_HDL(b) & SR_INT))&&(b->s<2))) return INT_TO_SR(1);
1044	if (SR_HDL(a) & SR_INT)
1045	{
1046	unsigned long t=mpz_gcd_ui(NULL,b->z,ABS(SR_TO_INT(a)));
1047	return INT_TO_SR(t);
1048	}
1049	else
1050	if (SR_HDL(b) & SR_INT)
1051	{
1052	unsigned long t=mpz_gcd_ui(NULL,a->z,ABS(SR_TO_INT(b)));
1053	return INT_TO_SR(t);
1054	}
1055	else
1056	{
1057	result=(number)omAllocBin(rnumber_bin);
1058	mpz_init(result->z);
1059	mpz_gcd(result->z,a->z,b->z);
1060	result->s = 3;
1061	#ifdef LDEBUG
1062	result->debug=123456;
1063	#endif
1064	result=nlShort3(result);
1065	}
1066	nlTest(result);
1067	return result;
1068	}
1069
1070	number nlShort1(number x) // assume x->s==0/1
1071	{
1072	assume(x->s<2);
1073	if (mpz_cmp_ui(x->z,(long)0)==0)
1074	{
1075	_nlDelete_NoImm(&x);
1076	return INT_TO_SR(0);
1077	}
1078	if (x->s<2)
1079	{
1080	if (mpz_cmp(x->z,x->n)==0)
1081	{
1082	_nlDelete_NoImm(&x);
1083	return INT_TO_SR(1);
1084	}
1085	}
1086	return x;
1087	}
1088	/*2
1089	* simplify x
1090	*/
1091	void nlNormalize (number &x)
1092	{
1093	if ((SR_HDL(x) & SR_INT) \|\|(x==NULL))
1094	return;
1095	if (x->s==3)
1096	{
1097	x=nlShort3_noinline(x);
1098	nlTest(x);
1099	return;
1100	}
1101	else if (x->s==0)
1102	{
1103	if (mpz_cmp_si(x->n,(long)1)==0)
1104	{
1105	mpz_clear(x->n);
1106	x->s=3;
1107	x=nlShort3(x);
1108	}
1109	else
1110	{
1111	mpz_t gcd;
1112	mpz_init(gcd);
1113	mpz_gcd(gcd,x->z,x->n);
1114	x->s=1;
1115	if (mpz_cmp_si(gcd,(long)1)!=0)
1116	{
1117	mpz_t r;
1118	mpz_init(r);
1119	MPZ_EXACTDIV(r,x->z,gcd);
1120	mpz_set(x->z,r);
1121	MPZ_EXACTDIV(r,x->n,gcd);
1122	mpz_set(x->n,r);
1123	mpz_clear(r);
1124	if (mpz_cmp_si(x->n,(long)1)==0)
1125	{
1126	mpz_clear(x->n);
1127	x->s=3;
1128	x=nlShort3_noinline(x);
1129	}
1130	}
1131	mpz_clear(gcd);
1132	}
1133	}
1134	nlTest(x);
1135	}
1136
1137	/*2
1138	* returns in result->z the lcm(a->z,b->n)
1139	*/
1140	number nlLcm(number a, number b, const ring r)
1141	{
1142	number result;
1143	nlTest(a);
1144	nlTest(b);
1145	if ((SR_HDL(b) & SR_INT)
1146	\|\| (b->s==3))
1147	{
1148	// b is 1/(b->n) => b->n is 1 => result is a
1149	return nlCopy(a);
1150	}
1151	result=(number)omAllocBin(rnumber_bin);
1152	#if defined(LDEBUG)
1153	result->debug=123456;
1154	#endif
1155	result->s=3;
1156	mpz_t gcd;
1157	mpz_init(gcd);
1158	mpz_init(result->z);
1159	if (SR_HDL(a) & SR_INT)
1160	mpz_gcd_ui(gcd,b->n,ABS(SR_TO_INT(a)));
1161	else
1162	mpz_gcd(gcd,a->z,b->n);
1163	if (mpz_cmp_si(gcd,(long)1)!=0)
1164	{
1165	mpz_t bt;
1166	mpz_init_set(bt,b->n);
1167	MPZ_EXACTDIV(bt,bt,gcd);
1168	if (SR_HDL(a) & SR_INT)
1169	mpz_mul_si(result->z,bt,SR_TO_INT(a));
1170	else
1171	mpz_mul(result->z,bt,a->z);
1172	mpz_clear(bt);
1173	}
1174	else
1175	if (SR_HDL(a) & SR_INT)
1176	mpz_mul_si(result->z,b->n,SR_TO_INT(a));
1177	else
1178	mpz_mul(result->z,b->n,a->z);
1179	mpz_clear(gcd);
1180	result=nlShort3(result);
1181	nlTest(result);
1182	return result;
1183	}
1184
1185	int nlModP(number n, int p)
1186	{
1187	if (SR_HDL(n) & SR_INT)
1188	{
1189	long i=SR_TO_INT(n);
1190	if (i<0L) return (((long)p)-((-i)%((long)p)));
1191	return i%((long)p);
1192	}
1193	int iz=(int)mpz_fdiv_ui(n->z,(unsigned long)p);
1194	if (n->s!=3)
1195	{
1196	int in=mpz_fdiv_ui(n->n,(unsigned long)p);
1197	#ifdef NV_OPS
1198	if (npPrimeM>NV_MAX_PRIME)
1199	return (int)((long)nvDiv((number)iz,(number)in));
1200	#endif
1201	return (int)((long)npDiv((number)iz,(number)in));
1202	}
1203	return iz;
1204	}
1205
1206	#ifdef HAVE_RINGS
1207	/*2
1208	* convert number i (from Q) to GMP and warn if denom != 1
1209	*/
1210	void nlGMP(number &i, number n)
1211	{
1212	// Hier brauche ich einfach die GMP Zahl
1213	nlTest(i);
1214	nlNormalize(i);
1215	if (SR_HDL(i) & SR_INT)
1216	{
1217	mpz_set_si((mpz_ptr) n, SR_TO_INT(i));
1218	return;
1219	}
1220	if (i->s!=3)
1221	{
1222	WarnS("Omitted denominator during coefficient mapping !");
1223	}
1224	mpz_set((mpz_ptr) n, i->z);
1225	}
1226	#endif
1227
1228	/*2
1229	* acces to denominator, other 1 for integers
1230	*/
1231	number nlGetDenom(number &n, const ring r)
1232	{
1233	if (!(SR_HDL(n) & SR_INT))
1234	{
1235	if (n->s==0)
1236	{
1237	nlNormalize(n);
1238	}
1239	if (!(SR_HDL(n) & SR_INT))
1240	{
1241	if (n->s!=3)
1242	{
1243	number u=(number)omAllocBin(rnumber_bin);
1244	u->s=3;
1245	#if defined(LDEBUG)
1246	u->debug=123456;
1247	#endif
1248	mpz_init_set(u->z,n->n);
1249	u=nlShort3_noinline(u);
1250	return u;
1251	}
1252	}
1253	}
1254	return INT_TO_SR(1);
1255	}
1256
1257	/*2
1258	* acces to Nominator, nlCopy(n) for integers
1259	*/
1260	number nlGetNumerator(number &n, const ring r)
1261	{
1262	if (!(SR_HDL(n) & SR_INT))
1263	{
1264	if (n->s==0)
1265	{
1266	nlNormalize(n);
1267	}
1268	if (!(SR_HDL(n) & SR_INT))
1269	{
1270	number u=(number)omAllocBin(rnumber_bin);
1271	#if defined(LDEBUG)
1272	u->debug=123456;
1273	#endif
1274	u->s=3;
1275	mpz_init_set(u->z,n->z);
1276	if (n->s!=3)
1277	{
1278	u=nlShort3_noinline(u);
1279	}
1280	return u;
1281	}
1282	}
1283	return n; // imm. int
1284	}
1285
1286	/***************************************************************
1287	*
1288	* routines which are needed by Inline(d) routines
1289	*
1290	*******************************************************************/
1291	BOOLEAN _nlEqual_aNoImm_OR_bNoImm(number a, number b)
1292	{
1293	assume(! (SR_HDL(a) & SR_HDL(b) & SR_INT));
1294	// long - short
1295	BOOLEAN bo;
1296	if (SR_HDL(b) & SR_INT)
1297	{
1298	if (a->s!=0) return FALSE;
1299	number n=b; b=a; a=n;
1300	}
1301	// short - long
1302	if (SR_HDL(a) & SR_INT)
1303	{
1304	if (b->s!=0)
1305	return FALSE;
1306	if (((long)a > 0L) && (mpz_isNeg(b->z)))
1307	return FALSE;
1308	if (((long)a < 0L) && (!mpz_isNeg(b->z)))
1309	return FALSE;
1310	mpz_t bb;
1311	mpz_init_set(bb,b->n);
1312	mpz_mul_si(bb,bb,(long)SR_TO_INT(a));
1313	bo=(mpz_cmp(bb,b->z)==0);
1314	mpz_clear(bb);
1315	return bo;
1316	}
1317	// long - long
1318	if (((a->s==1) && (b->s==3))
1319	\|\| ((b->s==1) && (a->s==3)))
1320	return FALSE;
1321	if (mpz_isNeg(a->z)&&(!mpz_isNeg(b->z)))
1322	return FALSE;
1323	if (mpz_isNeg(b->z)&&(!mpz_isNeg(a->z)))
1324	return FALSE;
1325	mpz_t aa;
1326	mpz_t bb;
1327	mpz_init_set(aa,a->z);
1328	mpz_init_set(bb,b->z);
1329	if (a->s<2) mpz_mul(bb,bb,a->n);
1330	if (b->s<2) mpz_mul(aa,aa,b->n);
1331	bo=(mpz_cmp(aa,bb)==0);
1332	mpz_clear(aa);
1333	mpz_clear(bb);
1334	return bo;
1335	}
1336
1337	// copy not immediate number a
1338	number _nlCopy_NoImm(number a)
1339	{
1340	assume(!((SR_HDL(a) & SR_INT)\|\|(a==NULL)));
1341	nlTest(a);
1342	number b=(number)omAllocBin(rnumber_bin);
1343	#if defined(LDEBUG)
1344	b->debug=123456;
1345	#endif
1346	switch (a->s)
1347	{
1348	case 0:
1349	case 1:
1350	mpz_init_set(b->n,a->n);
1351	case 3:
1352	mpz_init_set(b->z,a->z);
1353	break;
1354	}
1355	b->s = a->s;
1356	nlTest(b);
1357	return b;
1358	}
1359
1360	void _nlDelete_NoImm(number *a)
1361	{
1362	{
1363	switch ((*a)->s)
1364	{
1365	case 0:
1366	case 1:
1367	mpz_clear((*a)->n);
1368	case 3:
1369	mpz_clear((*a)->z);
1370	#ifdef LDEBUG
1371	(*a)->s=2;
1372	#endif
1373	}
1374	omFreeBin((ADDRESS) *a, rnumber_bin);
1375	}
1376	}
1377
1378	number _nlNeg_NoImm(number a)
1379	{
1380	{
1381	mpz_neg(a->z,a->z);
1382	if (a->s==3)
1383	{
1384	a=nlShort3(a);
1385	}
1386	}
1387	nlTest(a);
1388	return a;
1389	}
1390
1391	number _nlAdd_aNoImm_OR_bNoImm(number a, number b)
1392	{
1393	number u=(number)omAllocBin(rnumber_bin);
1394	#if defined(LDEBUG)
1395	u->debug=123456;
1396	#endif
1397	mpz_init(u->z);
1398	if (SR_HDL(b) & SR_INT)
1399	{
1400	number x=a;
1401	a=b;
1402	b=x;
1403	}
1404	if (SR_HDL(a) & SR_INT)
1405	{
1406	switch (b->s)
1407	{
1408	case 0:
1409	case 1:/* a:short, b:1 */
1410	{
1411	mpz_t x;
1412	mpz_init(x);
1413	mpz_mul_si(x,b->n,SR_TO_INT(a));
1414	mpz_add(u->z,b->z,x);
1415	mpz_clear(x);
1416	if (mpz_cmp_ui(u->z,(long)0)==0)
1417	{
1418	mpz_clear(u->z);
1419	omFreeBin((ADDRESS)u, rnumber_bin);
1420	return INT_TO_SR(0);
1421	}
1422	if (mpz_cmp(u->z,b->n)==0)
1423	{
1424	mpz_clear(u->z);
1425	omFreeBin((ADDRESS)u, rnumber_bin);
1426	return INT_TO_SR(1);
1427	}
1428	mpz_init_set(u->n,b->n);
1429	u->s = 0;
1430	break;
1431	}
1432	case 3:
1433	{
1434	if ((long)a>0L)
1435	mpz_add_ui(u->z,b->z,SR_TO_INT(a));
1436	else
1437	mpz_sub_ui(u->z,b->z,-SR_TO_INT(a));
1438	if (mpz_cmp_ui(u->z,(long)0)==0)
1439	{
1440	mpz_clear(u->z);
1441	omFreeBin((ADDRESS)u, rnumber_bin);
1442	return INT_TO_SR(0);
1443	}
1444	u->s = 3;
1445	u=nlShort3(u);
1446	break;
1447	}
1448	}
1449	}
1450	else
1451	{
1452	switch (a->s)
1453	{
1454	case 0:
1455	case 1:
1456	{
1457	switch(b->s)
1458	{
1459	case 0:
1460	case 1:
1461	{
1462	mpz_t x;
1463	mpz_init(x);
1464
1465	mpz_mul(x,b->z,a->n);
1466	mpz_mul(u->z,a->z,b->n);
1467	mpz_add(u->z,u->z,x);
1468	mpz_clear(x);
1469
1470	if (mpz_cmp_ui(u->z,(long)0)==0)
1471	{
1472	mpz_clear(u->z);
1473	omFreeBin((ADDRESS)u, rnumber_bin);
1474	return INT_TO_SR(0);
1475	}
1476	mpz_init(u->n);
1477	mpz_mul(u->n,a->n,b->n);
1478	if (mpz_cmp(u->z,u->n)==0)
1479	{
1480	mpz_clear(u->z);
1481	mpz_clear(u->n);
1482	omFreeBin((ADDRESS)u, rnumber_bin);
1483	return INT_TO_SR(1);
1484	}
1485	u->s = 0;
1486	break;
1487	}
1488	case 3: /* a:1 b:3 */
1489	{
1490	mpz_mul(u->z,b->z,a->n);
1491	mpz_add(u->z,u->z,a->z);
1492	if (mpz_cmp_ui(u->z,(long)0)==0)
1493	{
1494	mpz_clear(u->z);
1495	omFreeBin((ADDRESS)u, rnumber_bin);
1496	return INT_TO_SR(0);
1497	}
1498	if (mpz_cmp(u->z,a->n)==0)
1499	{
1500	mpz_clear(u->z);
1501	omFreeBin((ADDRESS)u, rnumber_bin);
1502	return INT_TO_SR(1);
1503	}
1504	mpz_init_set(u->n,a->n);
1505	u->s = 0;
1506	break;
1507	}
1508	} /switch (b->s) /
1509	break;
1510	}
1511	case 3:
1512	{
1513	switch(b->s)
1514	{
1515	case 0:
1516	case 1:/* a:3, b:1 */
1517	{
1518	mpz_mul(u->z,a->z,b->n);
1519	mpz_add(u->z,u->z,b->z);
1520	if (mpz_cmp_ui(u->z,(long)0)==0)
1521	{
1522	mpz_clear(u->z);
1523	omFreeBin((ADDRESS)u, rnumber_bin);
1524	return INT_TO_SR(0);
1525	}
1526	if (mpz_cmp(u->z,b->n)==0)
1527	{
1528	mpz_clear(u->z);
1529	omFreeBin((ADDRESS)u, rnumber_bin);
1530	return INT_TO_SR(1);
1531	}
1532	mpz_init_set(u->n,b->n);
1533	u->s = 0;
1534	break;
1535	}
1536	case 3:
1537	{
1538	mpz_add(u->z,a->z,b->z);
1539	if (mpz_cmp_ui(u->z,(long)0)==0)
1540	{
1541	mpz_clear(u->z);
1542	omFreeBin((ADDRESS)u, rnumber_bin);
1543	return INT_TO_SR(0);
1544	}
1545	u->s = 3;
1546	u=nlShort3(u);
1547	break;
1548	}
1549	}
1550	break;
1551	}
1552	}
1553	}
1554	nlTest(u);
1555	return u;
1556	}
1557
1558	number _nlSub_aNoImm_OR_bNoImm(number a, number b)
1559	{
1560	number u=(number)omAllocBin(rnumber_bin);
1561	#if defined(LDEBUG)
1562	u->debug=123456;
1563	#endif
1564	mpz_init(u->z);
1565	if (SR_HDL(a) & SR_INT)
1566	{
1567	switch (b->s)
1568	{
1569	case 0:
1570	case 1:/* a:short, b:1 */
1571	{
1572	mpz_t x;
1573	mpz_init(x);
1574	mpz_mul_si(x,b->n,SR_TO_INT(a));
1575	mpz_sub(u->z,x,b->z);
1576	mpz_clear(x);
1577	if (mpz_cmp_ui(u->z,(long)0)==0)
1578	{
1579	mpz_clear(u->z);
1580	omFreeBin((ADDRESS)u, rnumber_bin);
1581	return INT_TO_SR(0);
1582	}
1583	if (mpz_cmp(u->z,b->n)==0)
1584	{
1585	mpz_clear(u->z);
1586	omFreeBin((ADDRESS)u, rnumber_bin);
1587	return INT_TO_SR(1);
1588	}
1589	mpz_init_set(u->n,b->n);
1590	u->s = 0;
1591	break;
1592	}
1593	case 3:
1594	{
1595	if ((long)a>0L)
1596	{
1597	mpz_sub_ui(u->z,b->z,SR_TO_INT(a));
1598	mpz_neg(u->z,u->z);
1599	}
1600	else
1601	{
1602	mpz_add_ui(u->z,b->z,-SR_TO_INT(a));
1603	mpz_neg(u->z,u->z);
1604	}
1605	if (mpz_cmp_ui(u->z,(long)0)==0)
1606	{
1607	mpz_clear(u->z);
1608	omFreeBin((ADDRESS)u, rnumber_bin);
1609	return INT_TO_SR(0);
1610	}
1611	u->s = 3;
1612	u=nlShort3(u);
1613	break;
1614	}
1615	}
1616	}
1617	else if (SR_HDL(b) & SR_INT)
1618	{
1619	switch (a->s)
1620	{
1621	case 0:
1622	case 1:/* b:short, a:1 */
1623	{
1624	mpz_t x;
1625	mpz_init(x);
1626	mpz_mul_si(x,a->n,SR_TO_INT(b));
1627	mpz_sub(u->z,a->z,x);
1628	mpz_clear(x);
1629	if (mpz_cmp_ui(u->z,(long)0)==0)
1630	{
1631	mpz_clear(u->z);
1632	omFreeBin((ADDRESS)u, rnumber_bin);
1633	return INT_TO_SR(0);
1634	}
1635	if (mpz_cmp(u->z,a->n)==0)
1636	{
1637	mpz_clear(u->z);
1638	omFreeBin((ADDRESS)u, rnumber_bin);
1639	return INT_TO_SR(1);
1640	}
1641	mpz_init_set(u->n,a->n);
1642	u->s = 0;
1643	break;
1644	}
1645	case 3:
1646	{
1647	if ((long)b>0L)
1648	{
1649	mpz_sub_ui(u->z,a->z,SR_TO_INT(b));
1650	}
1651	else
1652	{
1653	mpz_add_ui(u->z,a->z,-SR_TO_INT(b));
1654	}
1655	if (mpz_cmp_ui(u->z,(long)0)==0)
1656	{
1657	mpz_clear(u->z);
1658	omFreeBin((ADDRESS)u, rnumber_bin);
1659	return INT_TO_SR(0);
1660	}
1661	u->s = 3;
1662	u=nlShort3(u);
1663	break;
1664	}
1665	}
1666	}
1667	else
1668	{
1669	switch (a->s)
1670	{
1671	case 0:
1672	case 1:
1673	{
1674	switch(b->s)
1675	{
1676	case 0:
1677	case 1:
1678	{
1679	mpz_t x;
1680	mpz_t y;
1681	mpz_init(x);
1682	mpz_init(y);
1683	mpz_mul(x,b->z,a->n);
1684	mpz_mul(y,a->z,b->n);
1685	mpz_sub(u->z,y,x);
1686	mpz_clear(x);
1687	mpz_clear(y);
1688	if (mpz_cmp_ui(u->z,(long)0)==0)
1689	{
1690	mpz_clear(u->z);
1691	omFreeBin((ADDRESS)u, rnumber_bin);
1692	return INT_TO_SR(0);
1693	}
1694	mpz_init(u->n);
1695	mpz_mul(u->n,a->n,b->n);
1696	if (mpz_cmp(u->z,u->n)==0)
1697	{
1698	mpz_clear(u->z);
1699	mpz_clear(u->n);
1700	omFreeBin((ADDRESS)u, rnumber_bin);
1701	return INT_TO_SR(1);
1702	}
1703	u->s = 0;
1704	break;
1705	}
1706	case 3: /* a:1, b:3 */
1707	{
1708	mpz_t x;
1709	mpz_init(x);
1710	mpz_mul(x,b->z,a->n);
1711	mpz_sub(u->z,a->z,x);
1712	mpz_clear(x);
1713	if (mpz_cmp_ui(u->z,(long)0)==0)
1714	{
1715	mpz_clear(u->z);
1716	omFreeBin((ADDRESS)u, rnumber_bin);
1717	return INT_TO_SR(0);
1718	}
1719	if (mpz_cmp(u->z,a->n)==0)
1720	{
1721	mpz_clear(u->z);
1722	omFreeBin((ADDRESS)u, rnumber_bin);
1723	return INT_TO_SR(1);
1724	}
1725	mpz_init_set(u->n,a->n);
1726	u->s = 0;
1727	break;
1728	}
1729	}
1730	break;
1731	}
1732	case 3:
1733	{
1734	switch(b->s)
1735	{
1736	case 0:
1737	case 1: /* a:3, b:1 */
1738	{
1739	mpz_t x;
1740	mpz_init(x);
1741	mpz_mul(x,a->z,b->n);
1742	mpz_sub(u->z,x,b->z);
1743	mpz_clear(x);
1744	if (mpz_cmp_ui(u->z,(long)0)==0)
1745	{
1746	mpz_clear(u->z);
1747	omFreeBin((ADDRESS)u, rnumber_bin);
1748	return INT_TO_SR(0);
1749	}
1750	if (mpz_cmp(u->z,b->n)==0)
1751	{
1752	mpz_clear(u->z);
1753	omFreeBin((ADDRESS)u, rnumber_bin);
1754	return INT_TO_SR(1);
1755	}
1756	mpz_init_set(u->n,b->n);
1757	u->s = 0;
1758	break;
1759	}
1760	case 3: /* a:3 , b:3 */
1761	{
1762	mpz_sub(u->z,a->z,b->z);
1763	if (mpz_cmp_ui(u->z,(long)0)==0)
1764	{
1765	mpz_clear(u->z);
1766	omFreeBin((ADDRESS)u, rnumber_bin);
1767	return INT_TO_SR(0);
1768	}
1769	u->s = 3;
1770	u=nlShort3(u);
1771	break;
1772	}
1773	}
1774	break;
1775	}
1776	}
1777	}
1778	nlTest(u);
1779	return u;
1780	}
1781
1782	// a and b are intermediate, but a*b not
1783	number _nlMult_aImm_bImm_rNoImm(number a, number b)
1784	{
1785	number u=(number)omAllocBin(rnumber_bin);
1786	#if defined(LDEBUG)
1787	u->debug=123456;
1788	#endif
1789	u->s=3;
1790	mpz_init_set_si(u->z,SR_TO_INT(a));
1791	mpz_mul_si(u->z,u->z,SR_TO_INT(b));
1792	nlTest(u);
1793	return u;
1794	}
1795
1796	// a or b are not immediate
1797	number _nlMult_aNoImm_OR_bNoImm(number a, number b)
1798	{
1799	assume(! (SR_HDL(a) & SR_HDL(b) & SR_INT));
1800	number u=(number)omAllocBin(rnumber_bin);
1801	#if defined(LDEBUG)
1802	u->debug=123456;
1803	#endif
1804	mpz_init(u->z);
1805	if (SR_HDL(b) & SR_INT)
1806	{
1807	number x=a;
1808	a=b;
1809	b=x;
1810	}
1811	if (SR_HDL(a) & SR_INT)
1812	{
1813	u->s=b->s;
1814	if (u->s==1) u->s=0;
1815	if ((long)a>0L)
1816	{
1817	mpz_mul_ui(u->z,b->z,(unsigned long)SR_TO_INT(a));
1818	}
1819	else
1820	{
1821	if (a==INT_TO_SR(-1))
1822	{
1823	mpz_set(u->z,b->z);
1824	mpz_neg(u->z,u->z);
1825	u->s=b->s;
1826	}
1827	else
1828	{
1829	mpz_mul_ui(u->z,b->z,(unsigned long)-SR_TO_INT(a));
1830	mpz_neg(u->z,u->z);
1831	}
1832	}
1833	if (u->s<2)
1834	{
1835	if (mpz_cmp(u->z,b->n)==0)
1836	{
1837	mpz_clear(u->z);
1838	omFreeBin((ADDRESS)u, rnumber_bin);
1839	return INT_TO_SR(1);
1840	}
1841	mpz_init_set(u->n,b->n);
1842	}
1843	else //u->s==3
1844	{
1845	u=nlShort3(u);
1846	}
1847	}
1848	else
1849	{
1850	mpz_mul(u->z,a->z,b->z);
1851	u->s = 0;
1852	if(a->s==3)
1853	{
1854	if(b->s==3)
1855	{
1856	u->s = 3;
1857	}
1858	else
1859	{
1860	if (mpz_cmp(u->z,b->n)==0)
1861	{
1862	mpz_clear(u->z);
1863	omFreeBin((ADDRESS)u, rnumber_bin);
1864	return INT_TO_SR(1);
1865	}
1866	mpz_init_set(u->n,b->n);
1867	}
1868	}
1869	else
1870	{
1871	if(b->s==3)
1872	{
1873	if (mpz_cmp(u->z,a->n)==0)
1874	{
1875	mpz_clear(u->z);
1876	omFreeBin((ADDRESS)u, rnumber_bin);
1877	return INT_TO_SR(1);
1878	}
1879	mpz_init_set(u->n,a->n);
1880	}
1881	else
1882	{
1883	mpz_init(u->n);
1884	mpz_mul(u->n,a->n,b->n);
1885	if (mpz_cmp(u->z,u->n)==0)
1886	{
1887	mpz_clear(u->z);
1888	mpz_clear(u->n);
1889	omFreeBin((ADDRESS)u, rnumber_bin);
1890	return INT_TO_SR(1);
1891	}
1892	}
1893	}
1894	}
1895	nlTest(u);
1896	return u;
1897	}
1898
1899	/*2
1900	* z := i
1901	*/
1902	number nlRInit (long i)
1903	{
1904	number z=(number)omAllocBin(rnumber_bin);
1905	#if defined(LDEBUG)
1906	z->debug=123456;
1907	#endif
1908	mpz_init_set_si(z->z,i);
1909	z->s = 3;
1910	return z;
1911	}
1912
1913	/*2
1914	* z := i/j
1915	*/
1916	number nlInit2 (int i, int j)
1917	{
1918	number z=(number)omAllocBin(rnumber_bin);
1919	#if defined(LDEBUG)
1920	z->debug=123456;
1921	#endif
1922	mpz_init_set_si(z->z,(long)i);
1923	mpz_init_set_si(z->n,(long)j);
1924	z->s = 0;
1925	nlNormalize(z);
1926	return z;
1927	}
1928
1929	number nlInit2gmp (mpz_t i, mpz_t j)
1930	{
1931	number z=(number)omAllocBin(rnumber_bin);
1932	#if defined(LDEBUG)
1933	z->debug=123456;
1934	#endif
1935	mpz_init_set(z->z,i);
1936	mpz_init_set(z->n,j);
1937	z->s = 0;
1938	nlNormalize(z);
1939	return z;
1940	}
1941
1942	#else // DO_LINLINE
1943
1944	// declare immedate routines
1945	number nlRInit (int i);
1946	BOOLEAN _nlEqual_aNoImm_OR_bNoImm(number a, number b);
1947	number _nlCopy_NoImm(number a);
1948	number _nlNeg_NoImm(number a);
1949	number _nlAdd_aNoImm_OR_bNoImm(number a, number b);
1950	number _nlSub_aNoImm_OR_bNoImm(number a, number b);
1951	number _nlMult_aNoImm_OR_bNoImm(number a, number b);
1952	number _nlMult_aImm_bImm_rNoImm(number a, number b);
1953
1954	#endif
1955
1956	/***************************************************************
1957	*
1958	* Routines which might be inlined by p_Numbers.h
1959	*
1960	*******************************************************************/
1961	#if defined(DO_LINLINE) \|\| !defined(P_NUMBERS_H)
1962
1963	// routines which are always inlined/static
1964
1965	/*2
1966	* a = b ?
1967	*/
1968	LINLINE BOOLEAN nlEqual (number a, number b)
1969	{
1970	nlTest(a);
1971	nlTest(b);
1972	// short - short
1973	if (SR_HDL(a) & SR_HDL(b) & SR_INT) return a==b;
1974	return _nlEqual_aNoImm_OR_bNoImm(a, b);
1975	}
1976
1977
1978	LINLINE number nlInit (int i, const ring r)
1979	{
1980	number n;
1981	LONG ii=(LONG)i;
1982	if ( ((ii << 3) >> 3) == ii ) n=INT_TO_SR(ii);
1983	else n=nlRInit(ii);
1984	nlTest(n);
1985	return n;
1986	}
1987
1988
1989	/*2
1990	* a == 1 ?
1991	*/
1992	LINLINE BOOLEAN nlIsOne (number a)
1993	{
1994	#ifdef LDEBUG
1995	if (a==NULL) return FALSE;
1996	nlTest(a);
1997	#endif
1998	return (a==INT_TO_SR(1));
1999	}
2000
2001	LINLINE BOOLEAN nlIsZero (number a)
2002	{
2003	return (a==INT_TO_SR(0));
2004	//return (mpz_cmp_si(a->z,(long)0)==0);
2005	}
2006
2007	/*2
2008	* copy a to b
2009	*/
2010	LINLINE number nlCopy(number a)
2011	{
2012	if ((SR_HDL(a) & SR_INT)\|\|(a==NULL))
2013	{
2014	return a;
2015	}
2016	return _nlCopy_NoImm(a);
2017	}
2018
2019
2020	/*2
2021	* delete a
2022	*/
2023	LINLINE void nlDelete (number * a, const ring r)
2024	{
2025	if (*a!=NULL)
2026	{
2027	nlTest(*a);
2028	if ((SR_HDL(*a) & SR_INT)==0)
2029	{
2030	_nlDelete_NoImm(a);
2031	}
2032	*a=NULL;
2033	}
2034	}
2035
2036	/*2
2037	* za:= - za
2038	*/
2039	LINLINE number nlNeg (number a)
2040	{
2041	nlTest(a);
2042	if(SR_HDL(a) &SR_INT)
2043	{
2044	int r=SR_TO_INT(a);
2045	if (r==(-(POW_2_28))) a=nlRInit(POW_2_28);
2046	else a=INT_TO_SR(-r);
2047	return a;
2048	}
2049	return _nlNeg_NoImm(a);
2050	}
2051
2052	/*2
2053	* u:= a + b
2054	*/
2055	LINLINE number nlAdd (number a, number b)
2056	{
2057	number u;
2058	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
2059	{
2060	LONG r=SR_HDL(a)+SR_HDL(b)-1L;
2061	if ( ((r << 1) >> 1) == r )
2062	return (number)(long)r;
2063	else
2064	return nlRInit(SR_TO_INT(r));
2065	}
2066	return _nlAdd_aNoImm_OR_bNoImm(a, b);
2067	}
2068
2069	number nlShort1(number a);
2070	number nlShort3_noinline(number x);
2071
2072	LINLINE number nlInpAdd (number a, number b, const ring r)
2073	{
2074	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
2075	{
2076	LONG r=SR_HDL(a)+SR_HDL(b)-1L;
2077	if ( ((r << 1) >> 1) == r )
2078	return (number)(long)r;
2079	else
2080	return nlRInit(SR_TO_INT(r));
2081	}
2082	// a=a+b
2083	if (SR_HDL(b) & SR_INT)
2084	{
2085	switch (a->s)
2086	{
2087	case 0:
2088	case 1:/* b:short, a:1 */
2089	{
2090	mpz_t x;
2091	mpz_init(x);
2092	mpz_mul_si(x,a->n,SR_TO_INT(b));
2093	mpz_add(a->z,a->z,x);
2094	mpz_clear(x);
2095	a->s = 0;
2096	a=nlShort1(a);
2097	break;
2098	}
2099	case 3:
2100	{
2101	if ((long)b>0L)
2102	mpz_add_ui(a->z,a->z,SR_TO_INT(b));
2103	else
2104	mpz_sub_ui(a->z,a->z,-SR_TO_INT(b));
2105	a->s = 3;
2106	a=nlShort3_noinline(a);
2107	break;
2108	}
2109	}
2110	return a;
2111	}
2112	if (SR_HDL(a) & SR_INT)
2113	{
2114	number u=(number)omAllocBin(rnumber_bin);
2115	#if defined(LDEBUG)
2116	u->debug=123456;
2117	#endif
2118	mpz_init(u->z);
2119	switch (b->s)
2120	{
2121	case 0:
2122	case 1:/* a:short, b:1 */
2123	{
2124	mpz_t x;
2125	mpz_init(x);
2126
2127	mpz_mul_si(x,b->n,SR_TO_INT(a));
2128	mpz_add(u->z,b->z,x);
2129	mpz_clear(x);
2130	// result cannot be 0, if coeffs are normalized
2131	mpz_init_set(u->n,b->n);
2132	u->s = 0;
2133	u=nlShort1(u);
2134	break;
2135	}
2136	case 3:
2137	{
2138	if ((long)a>0L)
2139	mpz_add_ui(u->z,b->z,SR_TO_INT(a));
2140	else
2141	mpz_sub_ui(u->z,b->z,-SR_TO_INT(a));
2142	// result cannot be 0, if coeffs are normalized
2143	u->s = 3;
2144	u=nlShort3_noinline(u);
2145	break;
2146	}
2147	}
2148	nlTest(u);
2149	return u;
2150	}
2151	else
2152	{
2153	switch (a->s)
2154	{
2155	case 0:
2156	case 1:
2157	{
2158	switch(b->s)
2159	{
2160	case 0:
2161	case 1: /* a:1 b:1 */
2162	{
2163	mpz_t x;
2164	mpz_t y;
2165	mpz_init(x);
2166	mpz_init(y);
2167	mpz_mul(x,b->z,a->n);
2168	mpz_mul(y,a->z,b->n);
2169	mpz_add(a->z,x,y);
2170	mpz_clear(x);
2171	mpz_clear(y);
2172	mpz_mul(a->n,a->n,b->n);
2173	a->s = 0;
2174	break;
2175	}
2176	case 3: /* a:1 b:3 */
2177	{
2178	mpz_t x;
2179	mpz_init(x);
2180	mpz_mul(x,b->z,a->n);
2181	mpz_add(a->z,a->z,x);
2182	mpz_clear(x);
2183	a->s = 0;
2184	break;
2185	}
2186	} /switch (b->s) /
2187	a=nlShort1(a);
2188	break;
2189	}
2190	case 3:
2191	{
2192	switch(b->s)
2193	{
2194	case 0:
2195	case 1:/* a:3, b:1 */
2196	{
2197	mpz_t x;
2198	mpz_init(x);
2199	mpz_mul(x,a->z,b->n);
2200	mpz_add(a->z,b->z,x);
2201	mpz_clear(x);
2202	mpz_init_set(a->n,b->n);
2203	a->s = 0;
2204	a=nlShort1(a);
2205	break;
2206	}
2207	case 3:
2208	{
2209	mpz_add(a->z,a->z,b->z);
2210	a->s = 3;
2211	a=nlShort3_noinline(a);
2212	break;
2213	}
2214	}
2215	break;
2216	}
2217	}
2218	nlTest(a);
2219	return a;
2220	}
2221	}
2222
2223	LINLINE number nlMult (number a, number b)
2224	{
2225	nlTest(a);
2226	nlTest(b);
2227
2228	if (a==INT_TO_SR(0)) return INT_TO_SR(0);
2229	if (b==INT_TO_SR(0)) return INT_TO_SR(0);
2230	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
2231	{
2232	LONG r=(SR_HDL(a)-1L)*(SR_HDL(b)>>1);
2233	if ((r/(SR_HDL(b)>>1))==(SR_HDL(a)-1L))
2234	{
2235	number u=((number) ((r>>1)+SR_INT));
2236	if (((((LONG)SR_HDL(u))<<1)>>1)==SR_HDL(u)) return (u);
2237	return nlRInit(SR_HDL(u)>>2);
2238	}
2239	return _nlMult_aImm_bImm_rNoImm(a, b);
2240	}
2241	return _nlMult_aNoImm_OR_bNoImm(a, b);
2242	}
2243
2244
2245	/*2
2246	* u:= a - b
2247	*/
2248	LINLINE number nlSub (number a, number b)
2249	{
2250	if (SR_HDL(a) & SR_HDL(b) & SR_INT)
2251	{
2252	LONG r=SR_HDL(a)-SR_HDL(b)+1;
2253	if ( ((r << 1) >> 1) == r )
2254	{
2255	return (number)(long)r;
2256	}
2257	else
2258	return nlRInit(SR_TO_INT(r));
2259	}
2260	return _nlSub_aNoImm_OR_bNoImm(a, b);
2261	}
2262
2263	#endif // DO_LINLINE
2264
2265	#ifndef P_NUMBERS_H
2266
2267	void nlInpGcd(number &a, number b, const ring r)
2268	{
2269	if ((SR_HDL(b)\|SR_HDL(a))&SR_INT)
2270	{
2271	number n=nlGcd(a,b,r);
2272	nlDelete(&a,r);
2273	a=n;
2274	}
2275	else
2276	{
2277	mpz_gcd(a->z,a->z,b->z);
2278	a=nlShort3_noinline(a);
2279	}
2280	}
2281	void nlInpIntDiv(number &a, number b, const ring r)
2282	{
2283	if ((SR_HDL(b)\|SR_HDL(a))&SR_INT)
2284	{
2285	number n=nlIntDiv(a,b);
2286	nlDelete(&a,r);
2287	a=n;
2288	}
2289	else
2290	{
2291	if (mpz_isNeg(a->z))
2292	{
2293	if (mpz_isNeg(b->z))
2294	{
2295	mpz_add(a->z,a->z,b->z);
2296	}
2297	else
2298	{
2299	mpz_sub(a->z,a->z,b->z);
2300	}
2301	mpz_add_ui(a->z,a->z,1);
2302	}
2303	else
2304	{
2305	if (mpz_isNeg(b->z))
2306	{
2307	mpz_sub(a->z,a->z,b->z);
2308	}
2309	else
2310	{
2311	mpz_add(a->z,a->z,b->z);
2312	}
2313	mpz_sub_ui(a->z,a->z,1);
2314	}
2315	MPZ_DIV(a->z,a->z,b->z);
2316	a=nlShort3_noinline(a);
2317	}
2318	}
2319	void nlInpMult(number &a, number b, const ring r)
2320	{
2321	if (((SR_HDL(b)\|SR_HDL(a))&SR_INT)
2322	)
2323	{
2324	number n=nlMult(a,b);
2325	nlDelete(&a,r);
2326	a=n;
2327	}
2328	else
2329	{
2330	mpz_mul(a->z,a->z,b->z);
2331	if (a->s==3)
2332	{
2333	if(b->s!=3)
2334	{
2335	mpz_init_set(a->n,b->n);
2336	a->s=0;
2337	}
2338	}
2339	else
2340	{
2341	if(b->s!=3)
2342	{
2343	mpz_mul(a->n,a->n,b->n);
2344	}
2345	a->s=0;
2346	}
2347	}
2348	}
2349
2350	number nlFarey(number nN, number nP)
2351	{
2352	mpz_t tmp; mpz_init(tmp);
2353	mpz_t A,B,C,D,E,N,P;
2354	if (SR_HDL(nN) & SR_INT) mpz_init_set_si(N,SR_TO_INT(nN));
2355	else mpz_init_set(N,nN->z);
2356	if (SR_HDL(nP) & SR_INT) mpz_init_set_si(P,SR_TO_INT(nP));
2357	else mpz_init_set(P,nP->z);
2358	assume(!mpz_isNeg(P));
2359	if (mpz_isNeg(N)) mpz_add(N,N,P);
2360	mpz_init_set_si(A,(long)0);
2361	mpz_init_set_ui(B,(unsigned long)1);
2362	mpz_init_set_si(C,(long)0);
2363	mpz_init(D);
2364	mpz_init_set(E,P);
2365	number z=INT_TO_SR(0);
2366	while(mpz_cmp_si(N,(long)0)!=0)
2367	{
2368	mpz_mul(tmp,N,N);
2369	mpz_add(tmp,tmp,tmp);
2370	if (mpz_cmp(tmp,P)<0)
2371	{
2372	// return N/B
2373	z=(number)omAllocBin(rnumber_bin);
2374	if (mpz_isNeg(B))
2375	{
2376	mpz_neg(B,B);
2377	mpz_neg(N,N);
2378	}
2379	mpz_init_set(z->z,N);
2380	mpz_init_set(z->n,B);
2381	z->s = 0;
2382	nlNormalize(z);
2383	break;
2384	}
2385	mpz_mod(D,E,N);
2386	mpz_div(tmp,E,N);
2387	mpz_mul(tmp,tmp,B);
2388	mpz_sub(C,A,tmp);
2389	mpz_set(E,N);
2390	mpz_set(N,D);
2391	mpz_set(A,B);
2392	mpz_set(B,C);
2393	}
2394	mpz_clear(tmp);
2395	mpz_clear(A);
2396	mpz_clear(B);
2397	mpz_clear(C);
2398	mpz_clear(D);
2399	mpz_clear(E);
2400	mpz_clear(N);
2401	mpz_clear(P);
2402	return z;
2403	}
2404	#if 0
2405	number nlMod(number a, number b)
2406	{
2407	if (((SR_HDL(b)&SR_HDL(a))&SR_INT)
2408	{
2409	int bi=SR_TO_INT(b);
2410	int ai=SR_TO_INT(a);
2411	int bb=ABS(bi);
2412	int c=ai%bb;
2413	if (c<0) c+=bb;
2414	return (INT_TO_SR(c));
2415	}
2416	number al;
2417	number bl;
2418	if (SR_HDL(a))&SR_INT)
2419	al=nlRInit(SR_TO_INT(a));
2420	else
2421	al=nlCopy(a);
2422	if (SR_HDL(b))&SR_INT)
2423	bl=nlRInit(SR_TO_INT(b));
2424	else
2425	bl=nlCopy(b);
2426	number r=nlRInit(0);
2427	mpz_mod(r->z,al->z,bl->z);
2428	nlDelete(&al);
2429	nlDelete(&bl);
2430	if (mpz_size1(&r->z)<=MP_SMALL)
2431	{
2432	LONG ui=(int)mpz_get_si(&r->z);
2433	if ((((ui<<3)>>3)==ui)
2434	&& (mpz_cmp_si(x->z,(long)ui)==0))
2435	{
2436	mpz_clear(&r->z);
2437	omFreeBin((ADDRESS)r, rnumber_bin);
2438	r=INT_TO_SR(ui);
2439	}
2440	}
2441	return r;
2442	}
2443	#endif
2444	#endif // not P_NUMBERS_H
2445	#endif // LONGRAT_CC

Note: See TracBrowser for help on using the repository browser.

Download in other formats: